Seal For A Single Serve Capsule

ABSTRACT

The invention relates to a single serve capsule ( 1 ) for preparing a beverage in a beverage preparation machine, said single serve capsule ( 1 ) having a liquid-tight base element ( 2 ) having a cavity ( 3 ) for receiving a beverage raw material and a capsule cover ( 4 ) sealing the cavity ( 3 ).

PRIOR ART

The present invention is based on a single-serve capsule for the preparation of a beverage in a beverage-production machine, where the single-serve capsule has a base element that is impermeable to liquid, with a cavity for the acceptance of a beverage raw material and a capsule lid closing the cavity.

Single-serve capsules of this type are known from the prior art. By way of example, the documents DE 10 2012 223 291 A1, DE 10 2013 215 274 A1, DE 10 2012 109 186 A1 and DE 10 2012 105 282 A1 disclose single-serve capsules for single-serve-capsule machines respectively having a rigid or semirigid base element which encloses a cavity for the acceptance of a beverage raw material, for example ground roast coffee, instant coffee, chocolate powder, tea blend, milk powder or the like, where a capsule lid is used to close the cavity after filling of the single-serve capsule. In order that the beverage raw material does not lose its flavor during storage and transport of the single-serve capsule, the base element is configured to be impermeable to gas and liquid. The base element must moreover withstand comparatively high mechanical forces during the production of the beverage, because the extraction liquid is introduced into the cavity under high pressure and at high temperature, in order to produce the beverage by interacting with the beverage raw material.

The single-serve capsules known from the prior art therefore typically use thermoformed base elements made of polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC) and/or polyethylene terephthalate (PET) and/or metal, in particular aluminum, because base elements of this type can be produced at low cost, and are mechanically stable, and also impermeable to gas and liquid.

DISCLOSURE OF THE INVENTION

It is an object of the present invention to provide a single-serve capsule of the type mentioned in the introduction which, after production of the beverage, permits easier, more environmentally friendly and less costly disposal, and/or which is easier to produce.

The object is achieved with a single-serve capsule for the preparation of a beverage in a beverage-production machine, where the single-serve capsule has a base element with a flange and with a cavity for the acceptance of a beverage raw material and a capsule lid closing the cavity, where the capsule lid is secured on the flange and there is a seal provided on the area opposite to the capsule lid, said seal provided being semiplastic.

The expositions provided in relation to this subject matter of the present invention apply equally to the other embodiments of the present invention, and vice versa. Features provided in connection with this embodiment of the present invention can be adopted in other aspects of the subject matter of the present invention.

The object is further achieved with a single-serve capsule for the preparation of a beverage in a beverage-production machine, where the single-serve capsule has a base element with a flange and with a cavity for the acceptance of a beverage raw material and a capsule lid closing the cavity, where the capsule lid is secured on the flange and there is a seal provided on the area opposite to the capsule lid, said seal provided being semielastic.

The expositions provided in relation to this subject matter of the present invention apply equally to the other embodiments of the present invention, and vice versa. Features provided in connection with this embodiment of the present invention can be adopted in other aspects of the subject matter of the present invention.

The following expositions apply equally to both aspects of the subject matter of the present invention.

These aspects of the subject matter of the present invention provide a single-serve capsule which is by way of example used for the production of beverages. The single-serve capsule is used by way of example to produce coffee or espresso or tea. For this purpose, the single-serve capsule has a base element with a base and side walls which enclose a cavity which is filled with the beverage raw material. The cavity is then closed by a capsule lid. For the production of the beverage, by way of example, hot water flows through the single-serve capsule.

It is preferable that the material used to manufacture the seal differs from that used to manufacture the base element. The base element has preferably been manufactured from a metallic material, in particular aluminum.

The single-serve capsule preferably has a side wall and a base. The side wall provided is preferably conical or cylindrical, and in particular connected to the base to form a one-piece element. At its end opposite to the base, the side wall has a flange which is in particular circular and which preferably is connected to the side wall to form a one-piece element, and provided at an angle to said side wall, in particular an obtuse angle.

On one side of the flange there is generally a capsule lid arranged, in particular sealed, where said lid seals a cavity in the base element in which a beverage raw material is located. The seal is provided on the flange side opposite to the capsule lid.

The seal provided in the invention is semiplastic and/or semielastic. After deformation, therefore, the seal does not remain in the deformed shape and/or does not resume its original shape. By way of example, the seal deforms semiplastically during the closure of the brewing chamber. A good sealing action is thus achieved, and the sealing action is also maintained at least to some extent when the closing pressure of the chamber components decreases. For the purposes of the invention, the word “semiplastically” implies that there is only partial shape-reversion of the impression that the brewing chamber impresses into the seal. The shape-reversion is preferably 10-40% of the maximal impression produced by the brewing chamber. The change of the cross section of the seal after deformation and shape-reversion preferably amounts to between 10 and 40%, based on the cross section of the seal before the deformation. The seal is accordingly semielastic, and undergoes partial shape-reversion after the pressure exerted by the brewing chamber has decreased. The seal therefore differs from an elastomeric seal which undergoes complete shape-reversion when the pressure exerted by the brewing chamber decreases. The seal also differs from a plastically deformable seal where the maximal deformation of the seal is at least in essence retained.

The seal preferably, or in the invention, comprises a biopolymer. It has preferably been manufactured entirely from a biopolymer.

Biopolymers in the present invention are polymers which are obtained from renewable feedstocks and/or are biodegradable, in particular completely biodegradable. The production of said biopolymers here can include extensive purification steps and/or modification steps. It is also possible in the invention to use mixtures of two or more biopolymers, and it is also possible here to use mixtures of two or more biopolymers of different classes, for example gelatins and polysaccharides or gelatins and cellulose or polysaccharides and cellulose, or else gelatins and polysaccharides and cellulose. These materials have the further advantage that the base elements obtained therefrom can be produced in compliance with vegan and/or kosher and/or halal requirements.

It is preferable that at least a partial region of the seal consists at least partially of gelatin, polysaccharides, polylactides, celluloses or mixtures of two or more of these biopolymers. The proportion of biopolymer in the material from which the seal is produced is preferably >30% by weight, preferably >40% by weight, with still greater preference >50% by weight and with most preference >55% by weight. The material preferably comprises glycerol and water. This mixture preferably comprises a crosslinking agent.

By way of example, a tannin is suitable as crosslinking agent.

The seal can also in particular consist entirely of biopolymer, in particular gelatin.

It is preferably that at least a partial region of the seal consists at least partially of gelatin and/or polysaccharide and/or cellulose. The proportion of gelatin and/or polysaccharide and/or cellulose in the material from which at least a partial region of the seal is produced is preferably >70% by weight, preferably >80% by weight, with still greater preference >90% by weight and with most preference >95% by weight. The seal can in particular also consist entirely of biopolymer.

It is preferable that at least a partial region of the seal consists at least partially of gelatin and/or hydroxypropylmethylcellulose and/or pullulan. The proportion of gelatin and/or hydroxypropyl-methylcellulose and/or pullulan in the material from which at least a partial region of the seal is produced is preferably >70% by weight, preferably >80% by weight, with still greater preference >90% by weight and with most preference >95% by weight. The seal can in particular also consist entirely of biopolymer.

Gelatin is preferably an animal protein, preferably a mixture of substances. Main constituent is preferably denatured or hydrolyzed collagen, which can be produced from the connective tissue of various animal species, especially pigs and cattle, but also fish and poultry. However, the gelatin can also be plant-derived gelatin, these mostly being polysaccharides.

Materials used as gelatin are preferably in particular gelatins of the type used in the field of pharmaceutical technology for the production of hard gelatin or of soft gelatin capsules. The gelatins can have been foamed. This foaming can be achieved by using a gas, in particular air.

The water content of the gelatins in the seal is preferably 1-50% by weight, preferably 6-20% by weight, with still greater preference 9-18% by weight, and with much more preference 9-16% by weight.

The Bloom value of the gelatins of the type used for the production of the seal can preferably be 10-350 Bloom, preferably 50-300 Bloom, with particular preference 150-280 Bloom, or 180-280 Bloom.

The gelatin has preferably been hardened and/or rendered insoluble in water. In an alternative to this, the gelatin has been hardened and/or rendered temporarily insoluble in water or temporarily resistant to moisture. The expression “gelatin that is temporarily insoluble in water or temporarily resistant to moisture” means by way of example gelatin that exhibits signs of decomposition after a certain time, for example after 1-28 days, in particular 1-14 days, with preference 1-7 days, with particular preference 1-5 days, after use of the capsule and/or exposure to environmental effects, for example moisture, insolation and/or the effect of microorganisms.

The above can be achieved by way of example via crosslinking of the product with one or more chemicals, i.e. in particular a procedure that effectively increases the molecular weight of the protein. Materials suitable for this purpose are by way of example alginic acid alkylene glycol derivatives, sodium-peroxide-oxidized alginic acid, amylopectin dialdehyde octenyl succinate, bisacryloylurea, bis(azidinethyl) sulfone, bis(bromoacetyl) ethylenediamine, bis(chloromethyl) adipate, bis(chloromethyl) diethylmalonate, bis(chloroacetyl) dimethylenediamine, benzene-disulfonyl fluoride, bromoacetic acid, carbodiimides, carboxybenzyl bromide, bis(chloroethyl)-urea, chromium acetate and chrome alums, cyanuric chloride, dialdehyde starch treated with caustic soda, dichlorohydroxy-s-triazine, sodium salt, dichloroquinoxoline carbonyl chloride, diethyleneurea, diformyldihydroxytrioxanonane, ditrioxynaphthalene, difluorodinitrobenzene, dihydroxydioxane, diglycidyl mono(propylene chlorohydrin) ether of glycerol, dihydroxymaleic acid, di(maleimido)benzene, di(maleimido)hexane, dimaleimide, dimethylaminophosphoryl, bis(dimethylamino)phosphoryl chloride, dimethylbis(vinylsulfonyl)benzene, disodium salt, tris(sulfate ethyl)sulfonium internal ether salts, ethylene glycol, ethoxymethyl isocyanate, formalin(formaldehyde, fluorosulfonylacetophenone, glycerol, gum arabic, for example oxidized with periodic acid, glutaraldehyde, hydroxytetramethylhydrooxazonium chloride, lactic acid, methotoluenesulfonate, mono-I-O-bromoethyl maleate, methylenediethanesulfonamide, haloalcohol methanesulfonate, mercaptoethylaziridine, methylglucanopyranoside, naphthalenedisulforyl fluoride, pectic acid, peroxydisulfate, phenol-formaldehyde resins, phenyltriazinidinylsilane, phloroformaline, phosphonitrile chloride, phloroglucinol, polyurethane, polyformal(s), polyacrolein, polyvinyl maleate, potassium permanganate, potassium ferrocyanide, pyromellitic anhydride, resorcinol diglycidyl ether, resorcinol, saccharide(s), sulfanilinodichloro-s-triazine, sodium hypochlorite, sodium salt of dichlorohydroxytriazine, stearylaminobenzoylacetic acid, sucrose, oxidized with periodate, tannin, tetrahydroxyphenol, trimellitic anhydride, trimethylenebis(isomaleimide), tris(chloroacetyl)hexahydrotriazine, tetraisopropyl titanate and/or a mixture of these made of at least two of the abovementioned substances.

Polysaccharide is the main constituent of the cell walls of plants. The polysaccharide provided preferably takes the form of cellulose, for example methylcellulose and/or hydroxypropylmethyl-cellulose and/or cellulose acetate. Other cellulose-based compounds can likewise be used. Alternatively, the polysaccharide provided can take the form of pullulan. The polysaccharide can be provided in the form of mixture of a plurality of substances. At least a partial region of the base element and/or of the capsule lid can moreover consist entirely or partially of cellulose, for example methylcellulose and/or hydroxypropylmethylcellulose and/or cellulose acetate. Other cellulose-based compounds can likewise be used.

The term “celluloses” in the invention can also mean derivatives thereof, in particular cellulose ethers, which are produced by partial or complete substitution of the hydrogen atoms of the hydroxy groups in the cellulose. These cellulose ethers can preferably be selected from the group consisting of carboxymethylcellulose, methylcellulose, ethylcellulose, hydroxyethylcellulose, hydroxypropylcellulose, methylethylcellulose, hydroxyethylmethyl-cellulose, hydroxypropylmethylcellulose, ethyl hydroxyethylcellulose and carboxymethylhydroxy-ethylcellulose. It is also possible in the invention here to use mixtures of two or more of said cellulose ethers.

Very particular preference is given to hydroxypropylmethylcellulose. A correspondingly suitable hydroxypropylmethylcellulose is by way of example also used in the production of hard vegan capsules in the field of pharmaceutical technology.

The water content of the hydroxypropylmethylcellulose in the seal is preferably 1-23% by weight, with still more preference 1.5-20% by weight, with much more preference 2.0-15% by weight and with most preference 2.5-10% by weight.

When the expression “plastic based on gelatin and/or polysaccharide and/or cellulose” is used below, it preferably means in particular plastic based on gelatin and/or hydroxypropylmethylcellulose and/or pullulan.

The biopolymer, in particular the plastic based on gelatin and/or polysaccharide and/or cellulose, is preferably provided in the form of film/foil, which is then molded, in particular thermoformed, in order to obtain the seal. However, it is also possible that the biopolymer, in particular the plastic, is liquefied and cast and/or applied through a nozzle, in order to obtain the desired shape of the seal. After casting, the biopolymer is hardened, in particular with exposure to low temperature. The resultant seal can be arranged on the base element, in particular at the flange thereof.

Alternatively, a shaped body corresponding to the required seal is preferably immersed singly or repeatedly in a liquid biopolymer, in particular a liquid plastics composition, until the desired thickness of material is achieved.

With still more preference, the biopolymer is placed into a channel which forms additional shaping at the exterior edge of the flange and of the capsule bodies, for example by using a nozzle, preferably while the single-serve capsule rotates. With very particular preference, at least a partial region of the base element, in particular the flange, is cooled before, during and/or after the application of the biopolymer, in particular of the gelatin.

The application of the biopolymer can take place after the closure of the single-serve capsule by a lid foil. However, it is also possible to provide the seal to the base element and then to fill, and close, the base element.

The biopolymer is by way of example hardened by means of drying, heat treatment and/or low-temperature treatment and/or crosslinking, for example by means of IV radiation or UV radiation, until the biopolymer, in particular the plastic, has solidified to the extent that it permits the use as base element together with the seal in particular in further production.

A seal with a plurality of layers can be produced by a repeated immersion of the shaped body. The shaped body can be immersed successively in various liquid biopolymers. The layers produced by the immersion in various liquid biopolymers can differ in respect of their optical properties or their UV resistance, hardness, deformability and/or resistance to liquids.

Preference is given to a foamed layer, in particular a foamed layer comprising gelatin. The foaming can by way of example be achieved by using a blowing gas. This layer is preferably combined with an adhesion-promoter layer, which with particular preference comprises gelatin. With particular preference, this adhesion-promoter layer improves the adhesion between the foamed layer and a metal base element, in particular a base element comprising aluminum. Another layer can be a protective protection layer which by way of example prevents softening and/or swelling of a biopolymer layer, in particular of a gelatin layer.

With very particular preference, the seal comprises a foamed gelatin layer and an adhesion-promoter layer which improves the adhesion to an aluminum base element, and a protective layer, which at least reduces, preferably prevents, softening and/or swelling, in particular of the foamed layer. The foamed layer preferably has a greater layer thickness than at least one other layer, preferably one of the other two layers.

It is preferable that at least that part of the surface of the base element, in particular of the collar/flange, that is in contact with the biopolymer, in particular with the gelatin, is pretreated in order to improve the adhesion between biopolymer and the base element, in particular a base element made of aluminum. This type of pretreatment can by way of example be a plasma treatment and/or a treatment with acid.

In this connection, the shaped body is advantageously an immersible shaped body corresponding to the seal, where the immersible shaped body has a shape with an immersible region which is immersed in the liquid biopolymer. The immersible region preferably corresponds to a negative of the shape of the required seal. During the production process, the immersible region of the shape is covered with a layer of the biopolymer. In a further step, the shaped body can be withdrawn from the liquid biopolymer. The biopolymer layer covering the shape of the shaped body can solidify, and can be dried. A corresponding process is known by way of example in the field of pharmacy as the Colton process for the production of pharmaceutical capsules. In particular, the covered shaped body can, during the solidification and/or drying procedure, be controlled in one or more dimensions in order to achieve targeted adjustment, in particular of the shape and/or the thickness, to the design of the base element.

The present invention also provides a process for the production of the single-serve capsule of the invention, where a shaped body is immersed in a biopolymer bath, and a film thus forms on the surface of the shaped body, and said film is then cooled and/or dried. Finally, the single-serve capsule is released from the shaped body and optionally also trimmed.

It is preferable that the biopolymer bath comprises gelatin.

It is preferable that additional shaping has been provided to the exterior edge of the flange.

It is preferable that the base element has been manufactured from metal, in particular aluminum.

The present invention further provides a process for the production of the seal of a single-serve capsule, where a shaped body is immersed in a biopolymer bath, and a film thus forms on the surface of the shaped body, and said film is then cooled and/or dried.

The expositions provided in relation to this subject matter of the present invention apply equally to the other embodiments of the present invention, and vice versa. Features provided in connection with this embodiment of the present invention can be adopted in other aspects of the subject matter of the present invention.

This subject matter of the present invention provides a process for the production of a seal of a single-serve capsule, where a shaped body is immersed in a biopolymer bath and a biopolymer film then adheres on said body, and said film solidifies there and then can be passed for further use. The film is optionally removed from the shaped body.

It is preferable that the shaped body is the negative of the required seal.

The present invention also provides a process for the production of a single-serve capsule where the gelatin is applied in the form of liquid or paste to the flange of the base element, and hardens there.

The expositions provided in relation to this subject matter of the present invention apply equally to the other embodiments of the present invention, and vice versa. Features provided in connection with this embodiment of the present invention can be adopted in other aspects of the subject matter of the present invention.

It is preferable that the base element of the single-serve capsule has the shape or surface on which a film of biopolymer adheres and solidifies and then forms the seal for the single-serve capsule. It is preferable that the flange side on which the film is applied is oriented in a manner such that gravity presses the film onto the flange, and that the film solidifies there. It is preferable that at least the flange is cooled before, during and/or after the application of the film. The film can be applied in that an application means and the base element move relative to one another, in particular rotate. It is possible to apply a plurality of layers.

The invention also provides a process for the production of the seal of a single-serve capsule, where a biopolymer, in particular the plastic based on gelatin and/or polysaccharide and/or cellulose, is provided in the form of film/foil which is then molded, in particular thermoformed, and where the molded foil is used as seal for the single-serve capsule.

The expositions provided in relation to this subject matter of the present invention apply equally to the other embodiments of the present invention, and vice versa. Features provided in connection with this embodiment of the present invention can be adopted in other aspects of the subject matter of the present invention.

The seal can be bonded to the base element by way of example by adhesive bonding or sealing.

The present invention also provides a process for the production of the seal of a single-serve capsule, where the biopolymer, in particular the plastic based on gelatin and/or polysaccharide and/or cellulose, is liquefied so that it can then be cast and/or sharpened, in order thus to obtain the desired shape of the seal.

The expositions provided in relation to this subject matter of the present invention apply equally to the other embodiments of the present invention, and vice versa. Features provided in connection with this embodiment of the present invention can be adopted in other aspects of the subject matter of the present invention.

In this subject matter of the present invention, the liquid biopolymer, in particular the gelatin, is liquefied or is already in liquid form when provided, and then is cast and/or injected into a mold and thus shaped to the shape of the seal.

It is preferable that the biopolymer is applied to the flange of the single-serve capsule and hardens there.

It is preferable that at least a partial region of a base element of the single-serve capsule is cooled before, during and/or after the application of the biopolymer.

The present invention also provides a process for the production of a beverage using a single-serve capsule of the invention, where the single-serve capsule, in particular the flange thereof, is clamped between two closing brewing-chamber elements, and the seal is thus deformed, and when the brewing-chamber elements are again opened only partial shape-reversion of the deformation then takes place.

The expositions provided in relation to this subject matter of the present invention apply equally to the other embodiments of the present invention, and vice versa. Features provided in connection with this embodiment of the present invention can be adopted in other aspects of the subject matter of the present invention.

In this subject matter of the present invention, the seal is deformed during closure of the brewing-chamber elements. The yield point of the biopolymer is exceeded here to an extent such that the deformation is semiplastic. This results in a very good sealing action, and the ejection of the single-serve capsule from the beverage-production apparatus is assisted.

Further details, features and advantages of the invention can be found from the drawings, and also from the description below of preferred embodiments with reference to the drawings. The drawings here merely illustrate examples of embodiments of the invention which do not restrict the essential concept of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic sectional view of a single-serve capsule in an example of an embodiment of the present invention.

EMBODIMENTS OF THE INVENTION

FIG. 1 is a diagram of a sectional view of a single-serve capsule 1 for the preparation of a beverage in a (not depicted) beverage-production machine in an example of an embodiment of the present invention.

The single-serve capsule 1 has a pot-shaped base element 2 and a capsule lid 4 secured on a peripheral flange 7 of the base element 2. The capsule lid 4 has in particular been welded or adhesively bonded to the flange 7. The base element 2 consists of a base region 6 and a wall region 8, these preferably being provided as a one-piece element. A cavity 3, filled with beverage raw material (for reasons of clarity not illustrated) and closed by the capsule lid 4, is configured within the base element 2. Arranged on the flange side opposite to the capsule lid (4) is a seal, which deforms during the closure of the brewing chamber. The seal has preferably been manufactured at least partially from gelatin. It is preferable that the seal material is applied in liquid form to the flange and hardens there, in particular in that the seal material is cooled. It is preferable here that the base element of the single-serve capsule is rotated by 180°, so that gravity presses the liquid seal material against the flange. It is preferable that the base element, in particular the flange, is cooled before application of the seal material. On opening of the brewing chamber, the deformation is only partially reversed. A deformation therefore remains in the seal after the opening of the brewing chamber. The seal undergoes partial elastic shape-reversion, but does not resume its original shape.

In use, the single-serve capsule 1 is introduced into a brewing chamber in a beverage-production machine. The brewing chamber is then closed, for example in that two brewing-chamber elements are moved relatively to one another. The capsule lid 4 and the base region 6 are perforated here, successively or simultaneously, and extraction liquid is introduced under pressure into the cavity 3 through the perforation apertures in the capsule lid 4. The interaction between the extraction liquid and the beverage raw material produces the desired beverage, which leaves the single-serve capsule 1 through the perforation apertures in the base region 6 and is introduced into a beverage vessel. Any possible particles of the beverage raw material are filtered from the beverage by the filter medium 9 and retained in the single-serve capsule 1. During the closing of the brewing-chamber elements, the seal 11 is deformed and therefore, after the brewing procedure, traces of the brewing chamber remain visible in the seal material, these however being smaller than the deformation of the seal during closure of the brewing chamber.

LIST OF REFERENCE SIGNS

-   1 Single-serve capsule -   2 Base element -   3 Cavity -   4 Capsule lid -   5 Partial region -   6 Base region -   7 Flange -   8 Wall region -   9 Filter medium -   10 Additional shaping -   11 Coating 

1. A single-serve capsule for a preparation of a beverage in a beverage-production machine, where the single-serve capsule has a base element with a flange and with a cavity for acceptance of a beverage raw material and a capsule lid closing the cavity, where the capsule lid is secured on the flange and there is a seal provided on an area opposite to the capsule lid, wherein the seal provided is partially plastic, and wherein the seal comprises gelatin.
 2. A single-serve capsule for a preparation of a beverage in a beverage-production machine, where the single-serve capsule has a base element with a flange and with a cavity for the acceptance of a beverage raw material and a capsule lid closing the cavity, where the capsule lid is secured on the flange and there is a seal provided on an area opposite to the capsule lid, characterized in that the seal provided is partially plastic, and wherein the seal comprises gelatin.
 3. (canceled)
 4. (canceled)
 5. The single-serve capsule as claimed in claim 1, wherein additional shaping has been provided to an exterior edge of the flange.
 6. The single-serve capsule as claimed in claim 1, wherein the base element has been manufactured from metal, in particular aluminum.
 7. The single-serve capsule as claimed in claim 1, wherein the seal comprises a foamed gelatin layer.
 8. The single-serve capsule as claimed in claim 7, wherein the foamed gelatin layer has, on a surface, a protective layer, in particular in relation to swelling and/or softening, and/or has, on a surface, in particular on another surface, preferably an opposite surface, an adhesion-promoter layer for improvement of adhesion of the foamed gelatin layer on the base element, in particular on an aluminum base element.
 9. A process for production of the seal of the single-serve capsule according to claim 1, where a shaped body corresponding to the seal is immersed in a biopolymer bath, and a film thus forms on a surface of the shaped body, and said film is then cooled and/or dried.
 10. A process for production of a seal of a single-serve capsule, wherein a biopolymer, in particular gelatin and/or polysaccharide and/or cellulose, is provided in a form of a film/foil which is then molded, in particular thermoformed, and where the molded foil is provided as the seal on the single-serve capsule.
 11. A process for production of a seal of a single-serve capsule, where a biopolymer, in particular the plastic based on gelatin and/or polysaccharide and/or cellulose, is liquefied so that it can then be cast and/or sharpened.
 12. A process for the production of a single-serve capsule as claimed in claim 1, wherein the gelatin is applied in a form of liquid or paste to the flange of the base element, and hardens there.
 13. The process as claimed in claim 12, wherein the gelatin is cooled.
 14. The process as claimed in claim 12, wherein the base element is cooled before, during and/or after the application of the gelatin.
 15. A process for production of a beverage using the single-serve capsule as claimed in claim 1, wherein the single-serve capsule, in particular the flange thereof, is clamped between two closing brewing-chamber elements, and the seal is thus deformed, and when the brewing-chamber elements are again opened only partial shape-reversion of the deformation then takes place.
 16. The single-serve capsule as claimed in claim 2, wherein additional shaping has been provided to an exterior edge of the flange.
 17. The single-serve capsule as claimed in claim 2, wherein the base element has been manufactured from metal, in particular aluminum.
 18. The single-serve capsule as claimed in claim 2, wherein the seal comprises a foamed gelatin layer.
 19. The single-serve capsule as claimed in claim 18, wherein the foamed gelatin layer has, on a surface, a protective layer, in particular in relation to swelling and/or softening, and/or has, on a surface, in particular on another surface, preferably an opposite surface, an adhesion-promoter layer for improvement of adhesion of the foamed gelatin layer on the base element, in particular on an aluminum base element.
 20. A process for production of the seal of the single-serve capsule according to claim 2, where a shaped body corresponding to the seal is immersed in a biopolymer bath, and a film thus forms on a surface of the shaped body, and said film is then cooled and/or dried.
 21. A process for production of a single-serve capsule as claimed in claim 2, wherein the gelatin is applied in a form of liquid or paste to the flange of the base element, and hardens there.
 22. The process as claimed in claim 21, wherein the gelatin is cooled.
 23. The process as claimed in claim 21, wherein the base element is cooled before, during and/or after the application of the gelatin.
 24. A process for production of a beverage using the single-serve capsule as claimed in claim 2, wherein the single-serve capsule, in particular the flange thereof, is clamped between two closing brewing-chamber elements, and the seal is thus deformed, and when the brewing-chamber elements are again opened only partial shape-reversion of the deformation then takes place. 